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Catch the Ball: Accurate High-Speed Motions for Mobile Manipulators via Inverse Dynamics Learning

Ke Dong, Karime Pereida, Florian Shkurti, Angela P. Schoellig

202032 citationsDOI

Abstract

Mobile manipulators consist of a mobile platform equipped with one or more robot arms and are of interest for a wide array of challenging tasks because of their extended workspace and dexterity. Typically, mobile manipulators are deployed in slow-motion collaborative robot scenarios. In this paper, we consider scenarios where accurate high-speed motions are required. We introduce a framework for this regime of tasks including two main components: (i) a bi-level motion optimization algorithm for real-time trajectory generation, which relies on Sequential Quadratic Programming (SQP) and Quadratic Programming (QP), respectively; and (ii) a learning-based controller optimized for precise tracking of high-speed motions via a learned inverse dynamics model. We evaluate our framework with a mobile manipulator platform through numerous high-speed ball catching experiments, where we show a success rate of 85.33%. To the best of our knowledge, this success rate exceeds the reported performance of existing related systems [1], [2] and sets a new state of the art.

Topics & Concepts

WorkspaceComputer scienceSequential quadratic programmingInverse dynamicsQuadratic programmingTrajectoryBall (mathematics)Mobile manipulatorMobile robotMotion controlControl theory (sociology)Artificial intelligenceRobotControl engineeringMathematical optimizationEngineeringMathematicsControl (management)KinematicsMathematical analysisAstronomyPhysicsClassical mechanicsRobotic Path Planning AlgorithmsRobotic Locomotion and ControlControl and Dynamics of Mobile Robots
Catch the Ball: Accurate High-Speed Motions for Mobile Manipulators via Inverse Dynamics Learning | Litcius